JP2003060736A - Transmitting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transmitting device equipped with an alarm transferring device capable of transferring alarm information on a network where a protocol that has a proper frame capable of realizing management on a network as well as client maintenance and a protocol that does not have such a proper frame coexist. SOLUTION: This transmitting device, connected to a network where transparent data transmission by a plurality of client protocols is performed and containing at least one among the plurality of client protocols, is provided with an alarm transferring device for notifying a transmitting device at an opposite station side of alarm information when a failure occurs through the network. The alarm transferring device notifies failure information with an alarm frame based on a prescribed client protocol unified among the plurality of client protocols.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission device, and more particularly, to alarm transfer in a network in which a protocol having a unique frame and a protocol having no such unique frame are mixed so that management on the network and maintenance of clients can be realized. The present invention relates to a transmission device including a device.

[0002]

2. Description of the Related Art In recent years, with the rapid increase in the number of Internet users, there has been a demand for the construction of a more reliable optical network for transmitting a large amount of data at high speed. WDM
(Wavelength Division Multiplexing)
Is a technology that seeks to address this issue by making more efficient use of existing optical fibers. WDM
Uses the property of light, that is, the property that lights of different wavelengths do not interfere with each other, multiplexes signals of multiple wavelengths in one optical fiber for transmission, and separates them by the receiver side. Is the method of sending the signal.

Currently, xDSL (Digital Subscriber Lin
e) etc., speeding up subscriber lines, multimedia data, or the spread of the Internet itself,
The amount of data that flows in the backbone of the Internet is increasing exponentially, and DWDM (Dense Wavelength Division Multiplexing) is used to increase the density of multiplexing to increase the speed and capacity of backbone networks.
The network is being constructed by.

As described above, networks mainly for optical transmission using DWDM have become mainstream now, and various applications and client protocols (transmission methods) based on the network architecture are used for optical transmission devices. Need to adapt. SONET / SDH (Sync
hronous Optical Network / Synchronous Digital Hierar
chy), Fast Ethernet / FDDI (Fast Ether)
There are net / Fiber Distributed Data Interface), Gigabit Ethernet, Fiber Channel, etc. (Ethernet is a registered trademark).

As a data transfer rate between clients, STS-3 / STM-1 in SONET / SDH
(155.52 Mbps), STS-12 / STM-4
(622.08 Mbps), and STS-48 / STM
-16 (2,488.32 Mbps) is used, 125 Mbps is used for Fast Ethernet / FDDI, and 1.25 Gbps is used for Gigabit Ethernet.
Is used for Fiber Channel and 132.8125
Mbps, 265.625 Mbps, 531.25 Mb
ps, and 1,062.5 Mbps are used. A network using DWDM is being constructed in order to perform bit-free transmission by adapting to such various client protocols.

FIG. 1 shows an example of an optical network using DWDM or the like. In FIG. 1, an optical signal from the terminal device 1 is transmitted via a relay device 2 to a network device 3 configured by DWDM or the like for performing n-wave optical multiplex transmission.
Entered in. Optical signals separated into respective signals are output from the network device 3, and each optical signal is received by the terminal station device 5 via the relay device 4. The same applies to the transmission of the optical signal from the terminal device 5 to the terminal device 1. Bit-free transmission is performed between the terminal devices 1 and 5, which are the opposite devices, based on the various client protocols described above.

[0007]

However, in the conventional network configuration, for example, when an input optical signal failure (data loss, loss of synchronization, etc.) occurs between the terminal device 1 and the relay device 2, the above-mentioned problem occurs. In the case of SONET / SDH, since the alarm transfer can be realized by a unique frame, it is possible to perform the alarm transfer when a failure occurs without depending on the network device 3, and it is easy to identify the failure occurrence point. However, other Gigabit Ethernet and FD that do not have a unique frame for network management
In a client protocol such as DI, when the above-mentioned failure occurs, there is a problem that the relay device 4 and the terminal device 5 on the opposite side cannot detect a clear alarm and it is difficult to isolate a clear failure part. It was An example is shown below.

2 to 4 show an example of a conventional alarm transfer method. In FIG. 2, due to a failure (marked with X) occurring on the input side, the relay device 2 causes the relay device 2 to lose the LOL (Loss of Light
t) or LOS (Loss of Signal) alarm signal is detected. Here, LOL is an alarm detected when the bit error rate (BER) of the received signal is 1 × 10 ⁻³ or more. The LOS is an alarm detected when the input signal disappears and the clock cannot be reproduced from the received signal.

As shown in the figure, these are SONET /
It is detected in all client protocols of SDH, Fast Ethernet / FDDI, Gigabit Ethernet, and Fiber Channel (marked with ●).
In this case, an alarm signal (AIS (Alarm Indication Sig) for notifying the occurrence of a fault is provided only in the case of SONET / SDH.
nal) -L) is generated and sent to the relay device 4 on the game side. Therefore, the relay device 4 on the game side receives the received AIS-
It is possible to easily know the occurrence of a failure on the relay device 2 side from L (marked with ●). Here, as an example, all “1” indicating that communication is impossible is transmitted to the terminal device 5.

FIG. 3 shows an example of the AIS in the SONET (STS-48) frame structure. As shown in FIG. 3, AIS information insert all "1" in the upper three bits of the K2 byte area / No. 1 the first byte in the overhead of the SONET / SDH frame _{(K2 # 1) (D 7} ~D 5) By doing so, it is coded as "AIS-L". At the time of AIS-L reception on the game side, "RDI (R
emote Detect Indication) -L ”code can be returned as response information.

Generally, the relay devices 2 and 4 are connected to the P inside the device.
A clock & data recovery (CDR; Cl) that synchronizes an internal clock using an LL circuit with a clock component of a received signal and reproduces internal data retimed by the internal clock.
ock & Data Recovery) function. When the input signal disappears and the clock cannot be recovered from the received signal, the LOS alarm is detected and the clock is switched to the free-running clock by the reference oscillator inside the device. In the case of SONET / SDH, a 2.488.32 MHz reference oscillator (15
5.52 MHz) is used, whereby an AIS-L alarm can be sent to the player side even after the LOS is detected.

On the other hand, the LOL or LOS alarm detected by Fast Ethernet / FDDI, Gigabit Ethernet, and Fiber Channel in FIG. Since it does not have such a unique frame for alarm transfer, there is no way to notify the relay device 4 on the game side of the occurrence of an alarm via the network device 3, and at present, the alarm transfer process has not been performed (◯: No. Operation). Therefore, in the network device 3, the relay device 4 and the terminal device 5 on the opposite side, there is a problem that it is difficult to determine the alarm occurrence section or the alarm occurrence point or it is difficult to judge the alarm.

Further, as described above, when the input signal is lost and LOS is detected, the clock is switched to the free-running clock by the reference oscillator inside the apparatus, but each client such as Fast Ethernet / FDDI, Gigabit Ethernet, and Fiber Channel is used. If the reference oscillator corresponding to the protocol is not inside the device, the above-mentioned SONET / SD
A normal PLL because it is asynchronous with the H reference oscillator
There is no control and therefore a normal transmission frame cannot be generated. Therefore, a plurality of reference oscillators for each client protocol and their switching peripheral circuits are required, which causes a problem that the circuit scale and the mounting scale are enlarged.

FIG. 4 shows an example of a control flow at the time of failure detection and failure recovery in a client protocol other than SONET / SDH. In the relay device 2 on the transmitting side, the error data received due to the fault occurring on the input side is directly transmitted (No Operation), and as a result L
When the OS is detected, the communication is continued by switching to the internal free-running clock (S101 to 104). Receiving side relay device 4
Then, a data error is detected (blocked) by receiving the error data, and when LOS is detected as a result, the internal free-running clock is switched to (S201 to 204).

When the failure on the side of the relay device 2 is recovered, the PLL clock pull-in is completed by the normal data input from the client, and the normal data transmission synchronized with the clock of the input data is started (S105-108). . As a result, the PLL device also pulls in the PLL clock on the receiving side, and normal data relay synchronized with the received data clock is restarted (S205 and S20).
6).

FIG. 5 shows an example of another conventional alarm transfer method. In this example, when the LOS / LOL alarm is detected on the side of the relay device 2 in which a failure has occurred (●
(Marked), the optical output of the channel (optical wavelength) in which the error is detected is shut down to prevent the influence of the failure on the channel which is operating normally (marked with ◯). As a result, regardless of the client protocol type, the relay device 4 on the game side can detect the LOS alarm due to the occurrence of the failure (marked with ●).

However, when the network device 3 transmits an optical wavelength division multiplexed signal by DWDM or the like as in this example, when the optical output of one channel is shut down, the network device 3 automatically outputs the total optical wavelength division multiplexed signal. There is a drawback that the network device 3 is involved in the monitoring and control of each channel by adjusting the power level gain. In particular, when the optical wavelength division multiplexed signal passes through a plurality of network devices 3, it takes a long time to adjust the level gain of the total optical power.

Therefore, an object of the present invention is to provide SONET / SDH which does not have the alarm transfer processing at the time of occurrence of the above-mentioned failure.
Another object of the present invention is to provide a transmission device equipped with an alarm transfer device that realizes an alarm detection / processing function equivalent to SONET / SDH without involving a network device in other client protocols. This allows
The location of the failure can be clearly identified, and the network can be operated smoothly.

More specifically, in an optical network in which a plurality of client protocols coexist, when a failure occurs between a terminal device and a relay device, its alarm transfer frame is converted into a SONET frame or a digital wrapper (DW). ; Digital Wrapper) Unified into a frame,
It is to provide a transmission device equipped with an alarm transfer device that adds alarm information (AIS / RDI, etc.) to the frame.

Thus, only one reference oscillator needs to be switched at the time of failure, and a plurality of reference oscillators for each client protocol are unnecessary. Further, the alarm information in the unified frame enables alarm transmission and detection between optical transmission devices without intervening network devices.

[0021]

According to the present invention, a failure occurs in a transmission device which is connected to a network for transparent data transmission by a plurality of client protocols and accommodates at least one of the plurality of client protocols. An alarm transfer device for notifying the transmission device on the game side of the alarm information at the time via the network,
The alarm transfer device is provided with a transmission device that notifies the failure information by an alarm frame based on a predetermined client protocol unified among the plurality of client protocols.

The alarm transfer device switches from the operating client protocol to the unified predetermined client protocol at the time of failure detection when a failure is detected, and switches from the unified predetermined client protocol to operation at the time of recovery from failure being detected. Switch to client protocol. The unified predetermined client protocol is a protocol having a unique frame for management / maintenance on the network, and the client protocol at the time of operation is a protocol having no unique frame for management / maintenance on the network. Is. The alarm frame is a SONET / SDH frame or a digital wrapper frame.

[0023]

6 and 7 are schematic representations of the operation according to the invention. FIG. 6 shows an operation example at the time of normal operation, and FIG. 7 shows an operation example at the time of failure occurrence. Here, as an alarm transfer method not related to the network device 3, alarm transfer of a client protocol that does not have a unique frame for alarm transfer is uniformly performed by a SONET transmission frame.

During normal operation of FIG. 6, the relay devices 2 and 4
SONET / SDH, Fast Ethernet /
Based on each client protocol specification such as FDDI, Gigabit Ethernet, or Fiber Channel, that is, each frame format and data transfer rate,
Network device 3 for transparent data transfer
Through.

When a failure occurs in FIG. 7, each client protocol of the relay device 2 detects LOL or LOS due to the failure (x mark) generated on the input side (● mark). If the client protocol is SONET / SDH,
A warning signal AIS-notifying the occurrence of a failure as in the conventional example of
L is generated and sent to the relay device 4 on the game side (○
mark). As a result, the relay device 4 on the game side receives the received AI.
Fault occurrence on the relay device 2 side can be detected from SL (●
mark).

Further, in this example, even when the client protocol is other than SONET / SDH, the alarm signal AIS-L for notifying the occurrence of a failure is similarly generated and sent to the relay device 4 on the game side (marked with a circle). As a result, the relay device 4 on the game side can detect the occurrence of a failure on the relay device 2 side from the received AIS-L (marked by ●). This is because not only switching from external synchronization to the internal clock that runs on its own, but also client protocol SONET at the time of clock switching when a failure of the relay devices 2 and 4 is detected.
It is realized by temporarily switching to / SDH.

Therefore, the reference clock required in the apparatus in this case is, for example, SONET / SDH 155.52 MH.
It may be one such as z. Also, in the failure processing of client protocols other than SONET / SDH, the existing SO
The hardware and software assets of NET / SDH can be shared, and the unification of the protocol for fault handling is also achieved.

8 to 13 show an embodiment of an optical transmission device which realizes the operation principle according to the present invention. Figure 8
Shows a first embodiment of the optical transmission apparatus according to the present invention. In the optical transmission device 2 on the transmission side, the optical fiber 11
The optical signal input from the optical-electrical conversion unit (O / E) 12
Is converted into an electric signal. In addition, the bit error rate (BE
Based on R), the LOL alarm is detected. The LOL alarm is input to the alarm detection unit 18 in the subsequent stage.

The electrical reception signal from the optical-electrical conversion unit 12 is a clock & data recovery unit (CDR; Clock & Data R).
ecovery) 14, where the PLL circuit 15 synchronizes the internal clock (C01) with the clock component of the received signal and reproduces the internal data (D01) retimed by the internal clock. The LOS detection circuit 16 detects the LOS when the input signal disappears and the clock cannot be reproduced from the received signal, and the LOS alarm is input to the alarm detection unit 18.

The reference oscillator (REF-OSC) 17 generates a free-running reference clock signal. In this example, the system is fixed to the 2,488.32 MHz system as in the conventional case, and the clock of the 2,488.32 MHz (C01 ') and the internal data (D01') retimed by the clock are frame-monitored by switching the clock at the time of failure. / Output to the generator unit 19.

The frame monitor / generator section 19
From the input internal clock (C01 or C01 ') and internal data (D01 or D01'), STS- in this example.
A data frame of 48 (2,488.32 Mbps) is generated (D02, C02). When a failure is detected, a predetermined header byte (K2 # 1) in this frame
The alarm information for which AIS-L is set is sent to.

The electrical-optical conversion section (E / O) 20 converts the data frame signal (D02, C02) from the frame monitor / generator section 19 into an optical signal and sends it to the network device 3 through the optical fiber 22. . On the other hand, the alarm detection unit 18 detects the three alarms LOL, LOS, and AIS described later, and notifies the alarm processing unit 21 of the detection of the alarms. In response to the notification, the alarm processing unit 21 receives the clock and data recovery unit 1
4 is instructed to switch the clock, and further, the frame monitor / generator unit 19 is set to switch to the STS-48 frame, which is a unified frame at the time of failure, and to set the AIS transmission.

The optical transmission device 4 on the receiving side is also similar to the above, and if it is blocked due to a data error, LOS or LOF is detected, so that the same operation processing is carried out using that signal as a trigger. The frame monitor / generator unit 19 also detects AIS-L information included in the received data from the game and outputs it to the alarm detection unit 18. And the terminal device 5
Is sent out for all "1".

FIG. 9 shows a more specific configuration example of FIG. In this example, a more specific configuration example of the frame monitor / generator unit 19 is particularly shown, and other than that, it is similar to FIG. 8 and will not be described further here. The frame monitor / generator unit 19 of this example is targeted for Gigabit Ethernet as a client protocol, and has a Gigabit Ethernet frame monitor / generator 24 and a SONET frame monitor / generator 25 for occurrence of a failure.

The SONET frame monitor / generator 25 can be realized as dedicated hardware integrated in the same chip as the Gigabit Ethernet frame monitor / generator 24, for example, or as shown in FIG.
A bit-free general-purpose frame monitor /
The SONET frame monitor / generator 25 can be realized by software by setting the generator and configuring the CPU of the alarm processing unit 21 and the processing operation.

The crosspoint switch 23 branches the input signal into 1: 2 and inputs it to both the Gigabit Ethernet frame monitor / generator 24 and the SONET frame monitor / generator 25. Selector (SE
L) 26 selects the Gigabit Ethernet frame monitor / generator 24 side during normal operation or after failure recovery according to an instruction from the alarm processing unit 21, and selects the SONET frame monitor / generator 25 side when a failure occurs.

10 and 11 show an example of the control flow in the embodiment of FIG. Also, FIGS.
3, the same content is shown in a timing chart. Hereinafter, the control flow of FIGS. 10 and 11 will be mainly described, but refer to FIGS. 12 and 13 as necessary.

In the relay device 2 on the transmission side shown in FIG. 10, the error data received due to a failure occurring on the input side during communication by the Gigabit Ethernet protocol is sent as it is (S101). As a result, when LOL or LOS is detected, a predetermined time (3 in this example) is set to prevent erroneous detection.
Second) timer is started (S302 and 303), and after its expiration, switching to the internal free-running clock, STS-4
Eight frame settings and AIS transmission settings are made (S304 to 306). This allows SONET / SD
ST of 2,488.32 Mbps based on H protocol
An alarm frame, which is an S-48 frame, in which AIS-L is set in the header part and all "1" is set in the payload part, is sent to the relay device 4 of the opposite station (S30).
7-309).

After that, when the failure on the relay device 2 side is recovered, normal data based on the Gigabit Ethernet protocol is received from the client, and LOL and LOS are received.
Again, the timer for a predetermined time (3 seconds in this example) is started to prevent erroneous detection (S311 and 312), and after the expiration, the AIS transmission stop setting, S
TS-48 frame release setting and switching to the external extraction clock are instructed (S313 to 315). As a result, the operation is restored to the Gigabit Ethernet and the PLL circuit 15 pulls in the clock to restore the normal data communication state (S316 to 319).

The relay device 4 on the receiving side shown in FIG. 11 is LOL or L depending on the error data received from the relay device 2 on the transmitting side during communication by the Gigabit Ethernet protocol.
The OS is detected, and a timer for a predetermined time (3 seconds in this example) is started on the receiving side to prevent erroneous detection (S4).
01-403). Upon the expiration, switching to the internal free-running clock and setting of the STS-48 frame are made (S
404 and 405), reception of AIS-L by STS-48 frame of 2,488.32 Mbps based on SONET / SDH protocol becomes possible (S406).
~ 408).

After that, when the failure on the relay apparatus 2 side is recovered, the transmission of the AIS-L from the relay apparatus 2 is stopped (S
410 and 413), an STS-48 frame release setting and an instruction to switch to the external extraction clock are issued (S).
411 and 412). As a result, the normal operation is restored to Gigabit Ethernet, and the PLL circuit 15 pulls in the clock to restore the normal data communication state (S414 to 416). 10 and 1
The distinction between the software processing and the hardware processing shown in 1 is for convenience and is not limited to this.

FIGS. 14 and 15 schematically show the alarm transfer operation according to the first embodiment described so far. As shown in FIG. 14, the alarm transfer operation after the clock is switched due to the occurrence of a failure is SONET /
The SDH protocol and other client protocols such as Fast Ethernet / FDDI, Gigabit Ethernet, and Fiber Channel are exactly the same. Therefore, according to the present invention, unified alarm transfer processing can be performed without being aware of each client protocol.

FIG. 15 is a diagram in which a response operation from the relay device 4 which receives an alarm is added to the alarm transfer operation of FIG. This response includes the RD of FIG. 3 described above.
LL is used. RDL-L itself is SONET / S
It is specified by the DH protocol, and therefore, in this example as well, unified alarm transfer processing and its response processing are possible without paying attention to each client protocol.

16 to 20 show another example of the mode of the optical transmission device for realizing the operation according to the present invention. Figure 1
6 shows a second embodiment of the optical transmission device according to the present invention. In this example, instead of using the SONET / SDH frame described so far with respect to the alarm processing, the ITU
-TG. 709 recommended digital wrapper (DW; Digit
al Wrapper) frame is used. Therefore, the frame monitor / generator unit 19 is provided with a bit-free type frame monitor / generator 27 for DW. The bit-free type frame monitor / generator 27 is composed of, for example, a multifunctional general-purpose communication controller, etc., and the CPU 28 of the alarm processing unit 21 performs frame format setting and software communication processing.

In addition, the digital wrapper is generally required to increase the data transmission rate by 7% because of encapsulation of transmission data. Therefore, the STS-48 (2,488.32) that requires the maximum data transmission rate for the reference oscillator 17 is used.
2.66 GHz (= 2,488.3) in consideration of MHz)
2 × 1.07) is used. It should be noted that the contents of the other components and the operation processing thereof are the same as those described in the first embodiment with reference to FIGS.
This is similar to the description of 1.

FIG. 17 shows an example of a 2.66 Gbps DW frame structure. 17A shows an example of a 2.66 Gbps DW frame in which the areas of columns 1-16 and rows 1-4 are used as the overhead area.
Here, as shown in FIG. 17B, frame synchronization is performed using the area of column 1 and row 1, and the other bits are all set to "1", so that SONET is set.
/ SDH constitutes an alarm frame corresponding to AIS-L.

In addition, as shown in FIG.
An example of a response frame corresponding to RDI-L in NET / SDH is realized by inserting "1" in the header "BDI" in the overhead. By making the same settings on both the transmitting and receiving stations, the transmission rate will be 2.6 when a failure occurs.
AIS and BDI (R) by 6 Gbps DW frame
DI) can be transmitted and received. As described above, in an optical network in which a plurality of client protocols coexist, the alarm transfer frame is unified into the DW frame, so that alarm transfer between relay devices and between terminal devices can be detected and detected.

FIGS. 18 and 19 schematically show the alarm transfer operation using the DW frame described above, and FIG. 1 using the SONET / SDH frame described above.
It corresponds to 4 and 15. As shown in FIG. 18, for the alarm transfer operation after the clock is switched due to the occurrence of a failure, the same DW frame is used including SONET / SDH protocol and other Fast Ethernet / FDDI, Gigabit Ethernet, and the like. Therefore, according to this example, unified alarm transfer processing can be performed without being aware of each client protocol.

FIG. 19 is a diagram in which a response operation from the relay device 4 which receives an alarm is added to the alarm transfer operation of FIG. The BDI of FIG. 17C is used for this response. Therefore, even in this example, unified alarm transfer processing and its response processing can be performed without paying attention to each client protocol.

(Supplementary Note 1) In a transmission device which is connected to a network for transparent data transmission by a plurality of client protocols and accommodates at least one of the plurality of client protocols, alarm information when a failure occurs is transmitted to the network. An alarm transfer device for notifying the transmission device on the opposite side via the alarm transfer device, wherein the alarm transfer device notifies the failure information by an alarm frame based on a predetermined client protocol unified among the plurality of client protocols. A transmission device characterized by.

(Supplementary Note 2) The alarm transfer device switches from the operating client protocol to the unified predetermined client protocol at the time of failure detection, and the unified predetermined client protocol at the time of recovery from failure is detected. To the client protocol at the time of operation. (Supplementary note 3) The transmission device according to supplementary note 2, wherein when the failure is detected, the clock is switched to the clock used in the unified predetermined client protocol, and when the recovery is detected, the clock is switched to the clock used in the client protocol in operation.

(Supplementary Note 4) When the alarm transfer device receives the alarm frame from the transmission device on the opposite side, it switches from the operating client protocol to the predetermined predetermined client protocol at the time of failure to eliminate the alarm frame. The transmission device according to claim 1, wherein the unified predetermined client protocol is switched to the operating client protocol according to. (Supplementary note 5) The transmission device according to supplementary note 4, wherein when the alarm frame is received, the clock is switched to the clock used in the unified predetermined client protocol, and when the alarm frame is resolved, the clock is switched to the clock used in the client protocol in operation. .

(Supplementary Note 6) The unified predetermined client protocol is a protocol having a unique frame for management / maintenance on the network, and the client protocol at the time of operation is for management / maintenance on the network. 6. The transmission device according to any one of appendices 2 to 5, which is a protocol having no unique frame. (Supplementary note 7) The warning frame is SONET / SDH.
7. The transmission device according to any one of appendices 1 to 6, which is a frame. (Supplementary note 8) The transmission device according to any one of supplementary notes 1 to 6, wherein the alarm frame is a digital wrapper frame.

[0054]

As described above, according to the present invention, SO which is a client protocol capable of performing management on the network and maintenance on the client side with a unique frame.
A terminal station in an optical network in which NET / SDH and client protocols such as Fast Ethernet / FDDI and Gigabit Ethernet, which are difficult to manage and maintain on the network because they do not have such a unique frame, are transmitted. It is possible to monitor and control alarms between relay devices by unifying alarm information about a fault that has occurred between the device and the relay device without putting a burden on the network devices that make up the optical network and by unifying the alarm frames. Become.

[Brief description of drawings]

FIG. 1 is a diagram showing an example of an optical network using DWDM or the like.

FIG. 2 is a diagram showing an example of a conventional alarm transfer method.

FIG. 3 is a diagram showing an example of AIS in a SONET (STS-48) frame.

FIG. 4 is a diagram showing an example of a control flow at the time of failure detection and failure recovery in a client protocol other than SONET / SDH.

FIG. 5 is a diagram showing an example of another conventional alarm transfer method.

FIG. 6 is a diagram schematically showing an operation during normal operation according to the present invention.

FIG. 7 is a diagram schematically showing an operation when a failure occurs according to the present invention.

FIG. 8 is a diagram showing a first embodiment of an optical transmission device according to the present invention.

9 is a diagram showing a more specific configuration example of FIG.

10 is a diagram showing an example (1) of the control flow in the embodiment of FIG.

11 is a diagram showing an example (2) of the control flow in the embodiment of FIG.

12 is a diagram showing an example (1) of control timing in the embodiment of FIG.

13 is a diagram showing an example (2) of control timing in the embodiment of FIG.

FIG. 14 is a diagram schematically showing an example (1) of the alarm transfer operation according to the first example of the present invention.

FIG. 15 is a diagram schematically showing an example (2) of the alarm transfer operation according to the first example of the present invention.

FIG. 16 is a diagram showing a second embodiment of the optical transmission device according to the present invention.

FIG. 17 is a diagram showing an example of a digital wrapper frame configuration.

FIG. 18 is a diagram schematically showing an example (1) of the alarm transfer operation according to the second example of the present invention.

FIG. 19 is a diagram schematically showing an example (2) of the alarm transfer operation according to the second example of the present invention.

[Explanation of symbols]

1, 5 ... Terminal device 2, 4 ... Relay device 3 ... Network device 11, 22 ... Optical fiber 12 ... Optical-electrical conversion unit 13 ... LOL detection unit 14 ... Clock & data recovery unit 15 ... PLL circuit 16 ... LOS detection Unit 17 ... Reference oscillator 18 ... Alarm detection unit 19 ... Frame monitor / generator unit 20 ... Electric-optical conversion unit 21 ... Alarm processing unit 23 ... Crosspoint switch 24 ... Gigabit Ethernet frame monitor / generator 25 ... SONET frame monitor / generator 26 ... Selector 27 ... Bit-free type frame monitor / generator 28 ... CPU

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Kazuhiko Omura             3-22-8, Hakata Station, Hakata-ku, Fukuoka City, Fukuoka Prefecture             Issue Fujitsu Kyushu Digital Technology Co., Ltd.             Inside the company (72) Inventor Katsuyuki Okabe             3-22-8, Hakata Station, Hakata-ku, Fukuoka City, Fukuoka Prefecture             Issue Fujitsu Kyushu Digital Technology Co., Ltd.             Inside the company (72) Inventor Oozaki Masakazu             4-1, Kamiodanaka, Nakahara-ku, Kawasaki-shi, Kanagawa             No. 1 within Fujitsu Limited F term (reference) 5B089 GA21 HA14 HB10 JB17 KA12                       KC23 KF06                 5K030 GA12 HB08 JA10 KX30 MA01                       MB01                 5K035 AA07 BB02 CC03 JJ01 JJ03                       MM03 MM06 MM08                 5K042 AA01 CA10 CA15 DA32 EA04                       EA14 FA25 HA13 JA08 NA03

Claims (5)

[Claims] 1. A transmission device connected to a network for transparent data transmission according to a plurality of client protocols and accommodating at least one of the plurality of client protocols, wherein warning information when a failure occurs is transmitted via the network. An alarm transfer device for notifying the transmission device on the opposite side is provided, and the alarm transfer device notifies the failure information by an alarm frame based on a predetermined client protocol unified among the plurality of client protocols. And transmission equipment. 2. The alarm transfer device switches from a client protocol at the time of operation to a unified predetermined client protocol at the time of failure detection, and operates from the unified predetermined client protocol at recovery detection from a failure. The transmission device according to claim 1, wherein the transmission protocol is switched to the client protocol at the time. 3. When the alarm transfer device receives the alarm frame from the transmission device on the opposite side, the alarm transfer device switches from the operating client protocol to the unified predetermined client protocol at the time of a failure, and the alarm frame is canceled to eliminate the alarm frame. 2. The transmission device according to claim 1, wherein the predetermined unified client protocol is switched to the operating client protocol. 4. The alarm frame is SONET / SD.
The transmission device according to claim 1, wherein the transmission device is an H frame. 5. The transmission device according to claim 1, wherein the alarm frame is a digital wrapper frame.